Coarse-grained stochastic models for tropical convection and climate
Prototype coarse-grained stochastic parametrizations for the interaction with unresolved features of tropical convection are developed here. These coarse-grained stochastic parametrizations involve systematically derived birth/death processes with low computational overhead that allow for direct int...
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ftunivmassamh:oai:scholarworks.umass.edu:math_faculty_pubs-1458 2023-06-11T04:16:37+02:00 Coarse-grained stochastic models for tropical convection and climate Khouider, B Majda, AJ Katsoulakis, MA 2003-01-01T08:00:00Z https://scholarworks.umass.edu/math_faculty_pubs/459 unknown ScholarWorks@UMass Amherst https://scholarworks.umass.edu/math_faculty_pubs/459 Mathematics and Statistics Department Faculty Publication Series Physical Sciences and Mathematics text 2003 ftunivmassamh 2023-05-04T18:57:45Z Prototype coarse-grained stochastic parametrizations for the interaction with unresolved features of tropical convection are developed here. These coarse-grained stochastic parametrizations involve systematically derived birth/death processes with low computational overhead that allow for direct interaction of the coarse-grained dynamical variables with the smaller-scale unresolved fluctuations. It is established here for an idealized prototype climate scenario that, in suitable regimes, these coarse-grained stochastic parametrizations can significantly impact the climatology as well as strongly increase the wave fluctuations about an idealized climatology. The current practical models for prediction of both weather and climate involve general circulation models (GCMs) where the physical equations for these extremely complex flows are discretized in space and time and the effects of unresolved processes are parametrized according to various recipes. With the current generation of supercomputers, the smallest possible mesh spacings are ≈50–100 km for short-term weather simulations and of order 200–300 km for short-term climate simulations. There are many important physical processes that are unresolved in such simulations such as the mesoscale sea-ice cover, the cloud cover in subtropical boundary layers, and deep convective clouds in the tropics. An appealing way to represent these unresolved features is through a suitable coarse-grained stochastic model that simultaneously retains crucial physical features of the interaction between the unresolved and resolved scales in a GCM. In recent work in two different contexts, the authors have developed both a systematic stochastic strategy (1) to parametrize key features of deep convection in the tropics involving suitable stochastic spin-flip models and also a systematic mathematical strategy to coarse-grain such microscopic stochastic models (2) to practical mesoscopic meshes in a computationally efficient manner while retaining crucial physical properties of the ... Text Sea ice University of Massachusetts: ScholarWorks@UMass Amherst |
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Physical Sciences and Mathematics |
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Physical Sciences and Mathematics Khouider, B Majda, AJ Katsoulakis, MA Coarse-grained stochastic models for tropical convection and climate |
topic_facet |
Physical Sciences and Mathematics |
description |
Prototype coarse-grained stochastic parametrizations for the interaction with unresolved features of tropical convection are developed here. These coarse-grained stochastic parametrizations involve systematically derived birth/death processes with low computational overhead that allow for direct interaction of the coarse-grained dynamical variables with the smaller-scale unresolved fluctuations. It is established here for an idealized prototype climate scenario that, in suitable regimes, these coarse-grained stochastic parametrizations can significantly impact the climatology as well as strongly increase the wave fluctuations about an idealized climatology. The current practical models for prediction of both weather and climate involve general circulation models (GCMs) where the physical equations for these extremely complex flows are discretized in space and time and the effects of unresolved processes are parametrized according to various recipes. With the current generation of supercomputers, the smallest possible mesh spacings are ≈50–100 km for short-term weather simulations and of order 200–300 km for short-term climate simulations. There are many important physical processes that are unresolved in such simulations such as the mesoscale sea-ice cover, the cloud cover in subtropical boundary layers, and deep convective clouds in the tropics. An appealing way to represent these unresolved features is through a suitable coarse-grained stochastic model that simultaneously retains crucial physical features of the interaction between the unresolved and resolved scales in a GCM. In recent work in two different contexts, the authors have developed both a systematic stochastic strategy (1) to parametrize key features of deep convection in the tropics involving suitable stochastic spin-flip models and also a systematic mathematical strategy to coarse-grain such microscopic stochastic models (2) to practical mesoscopic meshes in a computationally efficient manner while retaining crucial physical properties of the ... |
format |
Text |
author |
Khouider, B Majda, AJ Katsoulakis, MA |
author_facet |
Khouider, B Majda, AJ Katsoulakis, MA |
author_sort |
Khouider, B |
title |
Coarse-grained stochastic models for tropical convection and climate |
title_short |
Coarse-grained stochastic models for tropical convection and climate |
title_full |
Coarse-grained stochastic models for tropical convection and climate |
title_fullStr |
Coarse-grained stochastic models for tropical convection and climate |
title_full_unstemmed |
Coarse-grained stochastic models for tropical convection and climate |
title_sort |
coarse-grained stochastic models for tropical convection and climate |
publisher |
ScholarWorks@UMass Amherst |
publishDate |
2003 |
url |
https://scholarworks.umass.edu/math_faculty_pubs/459 |
genre |
Sea ice |
genre_facet |
Sea ice |
op_source |
Mathematics and Statistics Department Faculty Publication Series |
op_relation |
https://scholarworks.umass.edu/math_faculty_pubs/459 |
_version_ |
1768375016970256384 |